Apparatus and method for communicating signaling information

ABSTRACT

A User Equipment, UE, of a cellular communication system transmits scheduling assistance data to a base station comprising a base station scheduler which schedules packet data. The scheduling assistance data relates to packet data communication of the UE. The scheduling assistance data is generated by a scheduling assistance data generator coupled to a packet data transmit buffer associated with the packet data transmission. A first transport channel controller allocates other data to a first transport channel and a retransmission controller operates a retransmission scheme for this transport channel. A second transport channel controller allocates the scheduling assistance data to a signaling transport channel and a transport channel multiplexer combines the two transport channels as multiplexed channels on a single physical resource. The transmission reliabilities for the retransmission and non-retransmission transport channels may be individually optimized.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit of U.K. application GB 0508801.8 filed May 3, 2005. The contents of this document are incorporated herein by reference.

TECHNICAL FIELD

The invention relates to signaling of scheduling assistance data in a cellular communication system and in particular, but not exclusively, to signaling in a 3^(rd) Generation Partnership Project (3GPP) cellular communication system.

BACKGROUND ART

Currently, 3rd generation cellular communication systems are being rolled out to further enhance the communication services provided to mobile users. The most widely adopted 3rd generation communication systems are based on Code Division Multiple Access (CDMA) and Frequency Division Duplex (FDD) or Time Division Duplex (TDD). In CDMA systems, user separation is obtained by allocating different spreading and/or scrambling codes to different users on the same carrier frequency and in the same time intervals. In TDD user separation is achieved by assigning different time slots to different users in a similar way to TDMA. However, in contrast to TDMA, TDD provides for the same carrier frequency to be used for both uplink and downlink transmissions. An example of a communication system using this principle is the Universal Mobile Telecommunication System (UMTS). Further description of CDMA and specifically of the Wideband CDMA (WCDMA) mode of UMTS can be found in ‘WCDMA for UMTS’, Harri Holma (editor), Antti Toskala (Editor), Wiley & Sons, 2001, ISBN 0471486876.

In order to provide enhanced communication services, the 3rd generation cellular communication systems are designed for a variety of different services including packet based data communication. Likewise, existing 2^(nd) generation cellular communication systems, such as the Global System for Mobile communications (GSM) have been enhanced to support an increasing number of different services. One such enhancement is the General Packet Radio System (GPRS), which is a system developed for enabling packet data based communication in a GSM communication system. Packet data communication is particularly suited for data services which have a dynamically varying communication requirement such as for example Internet access services.

For cellular mobile communication systems in which the traffic and services have a non-constant data rate, it is efficient to dynamically share radio resources amongst users in accordance with their needs at a particular instant. This is in contrast to services with constant data rates, where radio resources appropriate for the service data rate can be assigned on a long-term basis such as for the duration of the call.

In the current UMTS TDD standards, uplink shared radio resources may be dynamically assigned (scheduled) by a scheduler in a Radio Network Controller (RNC). However, in order to operate efficiently, the scheduler needs to have knowledge of the volume of uplink data which is waiting for uplink transmission at the individual mobile users. This allows the scheduler to assign resources to users who need them most and in particular prevents that resource is wasted by being assigned to mobile stations that do not have any data to send.

A further aspect of efficient scheduling is the consideration of user radio channel conditions. A user for whom the radio path gain to another cell is similar to the radio path gain to the current serving cell may cause significant interference in the other cell. It can be shown that system efficiency may be significantly improved if the scheduler takes into account the relative path gains from the user to each cell in the particular locale of the network. In such schemes, the power of transmissions by users for whom the path gain to one or more non-serving cells is of similar magnitude to the path gain to the current serving cell is restricted such that the inter-cell interference caused is controlled and managed. Conversely, the transmit power of transmissions by users for whom the path gain to the serving cell is far greater than that to other cells is relatively less restricted since the inter-cell interference caused by such users per unit of transmission power is less.

In practical systems, both the radio conditions and the pending data volume status may change very rapidly. In order to optimize system efficiency as these changes occur, it is important that the scheduler in the network is informed of the very latest conditions such that timely adjustment of the scheduler operation may be effected.

For example, during a typical active session, there will be periodic spurts of uplink data to send (for example when sending an email, sending completed Internet forms, or when sending TCP acknowledgements for a corresponding downlink transfer, such as a web page). These short data spurts are known as packet calls, and their duration may span from typically a few milliseconds to a few seconds. During a packet call, uplink resources are being frequently allocated and it is efficient for the buffer volume and radio channel information to be piggybacked on these uplink transmissions to continually update the scheduler as to the data sending needs of the user. However, once the packet call has completed (all data to send has been sent and the transmission buffer is temporarily empty), allocation of uplink resources is suspended. In this situation, means for informing the scheduler of the arrival of new data (at the start of a new packet call) must be found. It is important to minimize any delay in this signaling since this contributes directly to the user-perceived transmission speed.

Release 99 of the Technical Specifications for 3GPP UMTS TDD, define a layer 3 message termed the PUSCH (Physical Uplink Shared Channel) Capacity Request (PCR) message. The logical channel carrying PCR (termed the Shared Channel Control Channel—SHCCH) may be routed to different transport channels depending on the presence of available resources. For example, the PCR message may be sent on the Random Access CHannel (RACH) which is terminated within the RNC. As another example, if the resources are available, the PCR may also in some cases be sent on the Uplink Shared CHannel (USCH).

However, although this approach is suitable for many applications it is not optimal for many other applications. For example, the defined signaling is aimed at providing scheduling information to RNC based schedulers and is designed for this application, and is in particular designed with a dynamic performance and delay suited for this purpose. Specifically, the signaling is relatively slow and the allocation response by the RNC scheduler is not particularly fast due to the delays associated with communication between the base station and the RNC (over the Iub interface) and the protocol stack delay in receiving the PCR and transmitting the allocation grant message via peer-to-peer layer 3 signaling.

Recently, significant effort has been invested in improving specifically uplink performance for 3GPP systems. One way to do this is to move the scheduling entity out of the RNC and into the base stations such that transmission and retransmission latencies may be reduced. As a result, a much faster and more efficient scheduling can be achieved. This in turn increases perceived end-user throughput. In such an implementation, a scheduler located in the base station (rather than in the RNC) assumes control over the granting of uplink resources. Fast scheduling response to user's traffic needs and channel conditions is desirable in improving the efficiency of the scheduling and the transmission delays for the individual mobile stations.

However, as the efficiency of the scheduling activity relies on sufficient information being available, the requirements for the signaling functionality become increasingly severe. Specifically, the existing approach wherein signaling is transmitted to the RNC by layer 3 signaling, is inefficient and introduces delays which limit the scheduling performance of a base station based scheduler. In particular, using techniques identical to the prior art (such as the use of PCR messages) are not attractive due to the fact that the transport channels used are terminated in the RNC—the signaling information thus ends up in a different network entity than that in which the scheduler resides and an additional delay is introduced in communicating this to the base station scheduler.

For example, in a 3GPP TDD system, timely updates on radio channel conditions are especially important due to the fact that the uplink and downlink radio channels are reciprocal. As such, if the user is able to inform the network scheduler of the very latest channel conditions (as e.g. measured on the downlink), and the scheduler is able to respond with minimal delay, then the scheduler may exploit the reciprocity and assume that the radio channel conditions will be relatively unchanged by the time an uplink transmission is scheduled and transmitted. The channel conditions that may be reported by a mobile station may include the channel conditions for the cell of the scheduler but may also include channel conditions relating to other cells thereby allowing a fast and efficient scheduling taking into account the instantaneous conditions for other cells and the resulting intercell interference caused.

As another example, in 3GPP FDD systems, mobile station buffer volume status is signalled within the uplink transmissions themselves. The data is contained within the same Protocol Data Unit (PDU) as the other uplink payload data—specifically in the MAC-e PDU header. However, this means that the signaling information is dependent on the performance and characteristics of the uplink data transmissions themselves.

In particular, the uplink data transmissions are designed for efficient throughput and characteristics suited for the data being transmitted.

The delay experienced by packet data transmissions may comprise a component due to the queuing of users and a component due to the transmission itself. In a loaded system, it is common that the queuing delay is larger than the transmission delay. The capacity of the system may be improved by using the radio resources more efficiently. Higher capacity can mean that users are served more quickly, and so the queuing delay may be reduced. However, some techniques, involving one or more air interface retransmissions, afford an increase in efficiency (and hence capacity) but at the expense of transmission delay. Thus a balance must be struck between queuing delay and transmission delay in order to find a system operating point which optimizes the system performance as perceived by the end-user. Typically many packet data services are relatively delay tolerant and the communication characteristics are therefore frequently aimed at an efficient transmission of data using a minimum of the air interface resource. Consequently, link efficiency is prioritized higher than transmission delay in order to reduce queuing delay for the data traffic. However, the consequential increased transmission delay may render the approach unsuitable for carrying control signaling information to a base station scheduler and may result in an inefficient scheduling by this scheduler.

Specifically, in order to achieve an efficient communication of data bits across the air interface, retransmission of data packets which are not correctly received has been specified for most 3GPP packet data services. In such systems, data retransmissions are commonplace and hybrid and fast retransmission schemes are typically used because the optimum link efficiency (in terms of the energy required per error-free transmitted bit following retransmissions) is achieved when the probability of error for first-time transmissions is relatively high (e.g. 10% to 50%). However, the air interface transmission delay associated with a retransmission is very high as it includes the delay of the acknowledgement feedback process (e.g. the delay of waiting for a possible acknowledgement before deciding to retransmit) and of the scheduling of a retransmission data packet.

Thus, current signaling techniques are suboptimal for many base station based schedulers. For example, uplink signaling techniques adopted for 3GPP FDD uplink suffer from latencies which, if applied to a TDD uplink system, may significantly degrade the performance of that TDD system with respect to the level of performance that is achievable.

Hence, an improved signaling in a cellular communication system would be advantageous and in particular a system allowing increased flexibility, reduced signaling delay, improved scheduling, suitability for base station based scheduling and/or improved performance would be advantageous.

SUMMARY OF THE INVENTION

Accordingly, the Invention seeks to preferably mitigate, alleviate or eliminate one or more of the abovementioned disadvantages singly or in any combination.

According to a first aspect of the invention, there is provided, an apparatus for transmitting signaling information in a cellular communication system; the apparatus comprising: means for generating scheduling assistance data for a base station based scheduler, the scheduling assistance data relating to packet data communication of a User Equipment; means for allocating the scheduling assistance data to a first transport channel; means for allocating other data to a second transport channel; means for transmitting the first and second transport channel as multiplexed transport channels on a first physical resource; wherein the second transport channel employs a retransmission scheme and the first transport channel does not employ a retransmission scheme.

The invention may allow improved scheduling by a base station based scheduler resulting in an improved performance of the cellular communication system as a whole. The invention may allow improved performance as perceived by the end-users. The invention may e.g. provide increased capacity, reduced delays and/or increased effective throughput. The invention may allow a flexible signaling and may allow the scheduling assistance data to be provided with short delays. The invention may in particular provide for signaling of scheduling assistance data which is particularly suitable for a scheduler based in a base station.

The invention may allow a single physical resource to provide an improved signaling of scheduling assistance data while allowing other data to be communicated with high link efficiency following retransmissions. In particular, delay may be reduced for signaling of scheduling assistance data while ensuring sufficient high reliability and link efficiency of other data. Individual trade offs between delay and link efficiency may be made for the transmission of scheduling assistance data and other data. The invention may be compatible with some existing communication systems, such as 3GPP cellular communication systems.

The scheduling assistance data may e.g. comprise an indication of an amount of data pending transmission at the UE and/or an indication of air interface channel conditions for the UE.

A physical resource may for example be a group of one or more physical channels of the cellular communication system. The packet data communication of the UE may e.g. be a shared uplink or downlink packet data service and/or channel.

The apparatus for receiving uplink signaling information may be the User Equipment.

According to an optional feature of the invention, the means for transmitting is arranged to transmit the first and second transport channels with different transmission reliabilities.

This may allow improved communication and may specifically allow low delay transmission of the scheduling assistance data while achieving high link efficiency for the second transport channel. The transmission reliabilities may be optimized for the individual characteristics and preferences for the transmission of the scheduling assistance data and for a data communication using retransmission. Thus, data packets transmitted on the first physical resource may comprise data of the first transport channel having one transmission reliability and data of the second transport channel having a different transmission reliability.

The means for transmitting may thus be arranged to transmit a data packet with different transmission reliabilities for data of the first transport channel and data of the second transport channel. Retransmissions may further affect the resulting received error rate and may in particular substantially avoid errors on the second transport channel.

According to an optional feature of the invention, the means for transmitting is arranged to transmit the first transmit channel with a lower bit error rate than for the second transport channel.

The data of the second transport channel may for example be transmitted with a data packet error rate more than ten times higher than for the first transport channel. This may allow efficient and low delay communication of the scheduling assistance data while providing high link efficiency and an efficient retransmission operation for the second transport channel. The bit error rate may relate to the bit error rate following forward error correcting decoding, i.e. the information bit rate following decoding but prior to retransmissions. The reliabilities of the first and second transport channels may be represented by block or packet error rate metrics following forward error correcting decoding.

The means for transmitting may thus be arranged to transmit a data packet with different bit error rates for data of the first transport channel and data of the second transport channel. Retransmissions may further affect the resulting received error rate and may in particular substantially avoid errors on the second transport channel.

According to an optional feature of the invention, the means for transmitting is arranged to transmit the first transport channel in accordance with a first transmission scheme and to transmit the second transport channel in accordance with a different second transmission scheme.

This may allow improved performance and may in particular allow efficient communication of other data while ensuring fast transmission for the scheduling assistance data. In particular it may allow a practical and low complexity implementation allowing individual optimization and trade offs for the communication of scheduling assistance data and other data using a common first physical resource.

According to an optional feature of the invention, the first transmission scheme and second transmission scheme comprise different error correcting encoding.

This may allow improved performance and may in particular allow efficient communication of other data while ensuring fast transmission for the scheduling assistance data. In particular it may allow a practical and low complexity implementation allowing individual optimization and trade offs for the communication of scheduling assistance data and other data using a common first physical resource. In particular the effective bit error rates/packet error rates may be effectively controlled to provide the desired performance.

According to an optional feature of the invention, the means for transmitting is arranged to perform rate matching of the first transport channel and the second transport channel.

The rate matching may be performed in order to adjust the error correcting capability of the first and second transport channels. This may allow improved performance and a practical implementation and may in particular provide improved sharing of the physical resource between at least the first and second transport channels.

According to an optional feature of the invention, the means for transmitting is arranged to apply different rate matching characteristics to the first transport channel and the second transport channel.

The different rate matching characteristics may be selected to result in different transmission reliabilities for the data of the first and second transport channel prior to retransmissions. This may allow improved performance and may in particular allow efficient communication of other data while ensuring fast transmission for the scheduling assistance data. In particular, it may allow a practical and low complexity implementation allowing individual optimization for the communication of scheduling assistance data and other data using a common first physical resource. In particular, the effective bit error rates/packet error rates may be effectively controlled to provide the desired performance. For example, the rate matching may use different code puncturing or channel symbol repetition characteristics for the first and second transport channels.

According to an optional feature of the invention, the first transport channel is terminated in a base station of the base station based scheduler.

This may allow improved scheduling and may in particular allow a faster and lower complexity signaling of scheduling assistance data. In particular, in existing cellular communication systems, a new transport channel may be introduced which is particularly suitable for scheduling performed at a base station and/or for shared communication of scheduling assistance data and other data.

According to an optional feature of the invention, the first transport channel has a different termination point than the second transport channel.

The first transport channel may be terminated in a different network entity than the second transport channel. For example, the first transport channel may be terminated at the base station while the second transport channel is terminated at an RNC. The feature may allow a particularly suitable signaling system and may allow faster signaling of scheduling assistance data and thus improved scheduling while allowing efficient sharing of physical resources.

According to an optional feature of the invention, the retransmission scheme is a Radio Network Controller controlled retransmission scheme.

This may allow improved performance in many communication systems and may for example allow scheduling assistance data to be effectively communicated to a base station based scheduler while allowing other data to be effectively controlled by a Radio Network Controller.

According to an optional feature of the invention, the retransmission scheme is a Base Station controlled retransmission scheme.

This may allow increased compatibility and/or improved performance in many communication systems.

According to an optional feature of the invention, the retransmission scheme is a Hybrid Automatic Repeat reQuest, ARQ, retransmission scheme.

This may allow increased compatibility with existing communication system and/or improved performance in many communication systems. In particular, it may allow a particularly efficient communication of other data on the same physical resource as used for communication of scheduling assistance data. Specifically, a Hybrid ARQ scheme may provide particularly high link efficiency if high packet data error rates can be used. In a Hybrid ARQ schemes previous transmissions of a data packet are in the receiver combined with the retransmissions of the data packet.

According to an optional feature of the invention, the apparatus further comprises means for transmitting the scheduling assistance data using a second physical resource and selection means for selecting between the first physical resource and the second physical resource.

This may improve performance and may allow a communication of the scheduling assistance data which is particularly suitable for the current conditions and the current characteristics of the physical resources. For example, in a 3GPP system, the apparatus may select between a physical random access channel (e.g. PRACH), a dedicated physical channel (e.g. DPCH) and/or an uplink channel scheduled by the base station based scheduler.

According to an optional feature of the invention, the selection means is arranged to select between the first physical resource and the second physical resource in response to an availability of the first physical resource and the second physical resource.

This may allow efficient signaling and may for example allow scheduling assistance data to be communicated on currently available resources thus allowing a dynamic system wherein the scheduling assistance data is communicated on different resources as and when they are available. Such an arrangement may in particular allow the signaling delay to be substantially reduced. For example, in a 3GPP system, the apparatus may select between a random access physical channel (e.g. PRACH), a dedicated physical channel (e.g. DPCH) and/or an uplink channel scheduled by the base station based scheduler depending on which of these channels are currently set up. The availability may for example be a duration since the physical resource was available.

According to an optional feature of the invention, the selection means is arranged to select between the first physical resource and the second physical resource in response to a traffic loading of the first physical resource and the second physical resource.

This may allow efficient signaling and may for example allow scheduling assistance data to be communicated on physical resources that have excess capacity. For example, in a 3GPP system, the apparatus may select between a physical random access channel (e.g. PRACH), a dedicated physical channel (e.g. DPCH) and/or an uplink channel scheduled by the base station based scheduler depending on which of these channels have spare capacity.

In some embodiments, the selection means is arranged to select between the first physical resource and the second physical resource in response to a latency characteristic associated with the first physical resource and the second physical resource.

This may allow efficient signaling and may for example allow scheduling assistance data to be communicated on the physical resource that results in the lowest delay for the scheduling assistance data. This may provide improved performance and scheduling due to reduced delay. The latency characteristic may e.g. be an estimated, assumed or calculated delay for transmission of the scheduling assistance data on each physical resource.

According to an optional feature of the invention, the first physical resource is not managed by the base station based scheduler.

This may provide efficient and low delay signaling of scheduling assistance data. The data on the first physical resource is not scheduled by the base station based scheduler. Rather the data on the first physical resource may for example be scheduled by a scheduler of the RNC supporting the base station of the base station based scheduler. The first physical resource may be a resource which the base station based scheduler does not have any controlling relationship with and/or information of.

According to an optional feature of the invention, the second physical resource is a physical resource managed by the base station based scheduler.

The second physical resource may support data which is scheduled by the base station based scheduler. The second physical resource may specifically support a user data channel for which the base station based scheduler schedules the information. For example, in a 3GPP system, the apparatus may select between a physical random access channel (e.g. PRACH), a dedicated physical channel (e.g. DPCH) controlled by an RNC scheduler and/or a packet data uplink channel which is scheduled by the base station based scheduler.

According to an optional feature of the invention, the first physical resource is associated with the first transport channel and the second physical resource is associated with a third transport channel and the selection means is arranged to allocate the scheduling assistance data by associating the scheduling assistance data with the first or third transport channel.

This may provide a highly advantageous approach and may in particular allow an efficient selection of the appropriate physical resource while allowing individual optimisation of transmission characteristics for the scheduling assistance data. The transport channels may be selected in response to characteristics associated with the physical resource of the transport channel. The third transport channel may in some embodiments be the same as the second transport channel.

According to an optional feature of the invention, the first physical resource is a random access channel

The random access channel may provide a particularly suitable channel as it may be used when no other physical channels are available.

According to an optional feature of the invention, the packet data communication is an uplink packet data communication. The invention may provide particularly advantageous performance for an uplink packet data communication service which may specifically be an uplink packet data communication service.

According to an optional feature of the invention, the cellular communication system is a 3^(rd) Generation Partnership Project, 3GPP, system.

The 3GPP system may specifically be a UMTS cellular communication system. The invention may allow improved performance in a 3GPP cellular communication system.

According to an optional feature of the invention, the cellular communication system is a Time Division Duplex system.

The invention may allow improved performance in a TDD cellular communication system and may in particular allow improved scheduling by exploiting the improved signaling of channel condition information applicable to both uplink and downlink channels.

According to a second aspect of the invention, there is provided an apparatus for receiving signaling information in a cellular communication system; the apparatus comprising: means for receiving a first physical resource comprising a first transport channel and a second transport channel as multiplexed transport channels; means for extracting scheduling assistance data for a base station based scheduler from the first transport channel, the scheduling assistance data relating to packet data communication of a User Equipment; means for extracting other data from the second transport channel; and wherein the second transport channel employs a retransmission scheme and the first transport channel does not employ a retransmission scheme.

It will be appreciated that the optional features, comments and/or advantages described above with reference to the apparatus for transmitting uplink signaling information apply equally well to the apparatus for receiving uplink signaling information and that the optional features may be included in the apparatus for receiving uplink signaling information individually or in any combination.

The apparatus for receiving uplink signaling information may be a base station.

According to a third aspect of the invention, there is provided a method of transmitting signaling information in a cellular communication system; the method comprising: generating scheduling assistance data for a base station based scheduler, the scheduling assistance data relating to packet data communication of a User Equipment; allocating the scheduling assistance data to a first transport channel; allocating other data to a second transport channel; transmitting the first transport channel and second transport channel as multiplexed transport channels on a first physical resource; and wherein the second transport channel employs a retransmission scheme and the first transport channel does not employ a retransmission scheme.

It will be appreciated that the optional features comments and/or advantages described above with reference to the apparatus for transmitting uplink signaling information apply equally well to the method for transmitting uplink signaling information and that the optional features may be included in the method for transmitting uplink signaling information individually or in any combination.

For example, in accordance with an optional feature of the invention, the first transport channel and the second transport channel are transmitted with different transmission reliabilities.

As another example, in accordance with an optional feature of the invention, the first transport channel is transmitted in accordance with a first transmission scheme and the second transport channel is transmitted in accordance with a different second transmission scheme.

As another example, in accordance with an optional feature of the invention, the first transport channel is terminated in a base station of the base station based scheduler.

According to a fourth aspect of the invention, there is provided a method of receiving signaling information in a cellular communication system; the method comprising: receiving a first physical resource comprising a first transport channel and a second transport channel as multiplexed transport channels; extracting scheduling assistance data for a base station based scheduler from the first transport channel, the scheduling assistance data relating to packet data communication of a User Equipment; extracting other data from the second transport channel; and wherein the second transport channel employs a retransmission scheme and the first transport channel does not employ a retransmission scheme.

These and other aspects, features and advantages of the invention will be apparent from and elucidated with reference to the embodiment(s) described hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be described, by way of example only, with reference to the drawings, in which

FIG. 1 illustrates an example of a cellular communication system 100 in which embodiments of the invention may be employed;

FIG. 2 illustrates a UE, an RNC and a base station in accordance with some embodiments of the invention;

FIG. 3.a illustrates an example of the switching of a single transport channel between uplink physical resource types;

FIG. 3.b illustrates an example of the switching of the signaling information stream into two or more transport channels each of which has a fixed association with a physical resource type; and

FIG. 4 illustrates and example of a signaling system in accordance with some embodiments of the invention.

DETAILED DESCRIPTION OF THE INVENTION

The following description focuses on embodiments of the invention applicable to a UMTS (Universal Mobile Telecommunication System) cellular communication system and in particular to a UMTS Terrestrial Radio Access Network (UTRAN) operating in a Time Division Duplex (TDD) mode. However, it will be appreciated that the invention is not limited to this application but may be applied to many other cellular communication systems including for example a GSM (Global System for Mobile communication system) cellular communication system.

FIG. 1 illustrates an example of a cellular communication system 100 in which embodiments of the invention may be employed.

In a cellular communication system, a geographical region is divided into a number of cells each of which is served by a base station. The base stations are interconnected by a fixed network which can communicate data between the base stations. A mobile station is served via a radio communication link by the base station of the cell within which the mobile station is situated.

As a mobile station moves, it may move from the coverage of one base station to the coverage of another, i.e. from one cell to another. As the mobile station moves towards a base station, it enters a region of overlapping coverage of two base stations and within this overlap region it changes to be supported by the new base station. As the mobile station moves further into the new cell, it continues to be supported by the new base station. This is known as a handover or handoff of a mobile station between cells.

A typical cellular communication system extends coverage over typically an entire country and comprises hundreds or even thousands of cells supporting thousands or even millions of mobile stations. Communication from a mobile station to a base station is known as uplink, and communication from a base station to a mobile station is known as downlink.

In the example of FIG. 1, a first User Equipment (UE) 101 and a second UE 103 are in a first cell supported by a base station 105. A UE may be for example a remote unit, a mobile station, a communication terminal, a personal digital assistant, a laptop computer, an embedded communication processor or any communication element communicating over the air interface of the cellular communication system.

The base station 105 is coupled to an RNC 107. An RNC performs many of the control functions related to the air interface including radio resource management and routing of data to and from appropriate base stations.

The RNC 107 is coupled to a core network 109. A core network interconnects RNCs and is operable to route data between any two RNCs, thereby enabling a remote unit in a cell to communicate with a remote unit in any other cell. In addition, a core network comprises gateway functions for interconnecting to external networks such as the Public Switched Telephone Network (PSTN), thereby allowing mobile stations to communicate with landline telephones and other communication terminals connected by a landline. Furthermore, the core network comprises much of the functionality required for managing a conventional cellular communication network including functionality for routing data, admission control, resource allocation, subscriber billing, mobile station authentication etc.

It will be appreciated that for clarity and brevity only the specific elements of the cellular communication system required for the description of some embodiments of the invention are shown, and that the cellular communication may comprise many other elements including other base stations and RNCs as well as other network entities such as SGSNs, GGSNs, HLRs, VLRs etc.

Conventionally, the scheduling of data over the air interface is performed by the RNC. However, recently packet data services have been proposed which seek to exploit the fluctuating channel conditions when scheduling data over a shared channel. Specifically, a High Speed Downlink Packet Access (HSDPA) service is currently being standardized by 3GPP. HSDPA allows scheduling to be performed taken the conditions for the individual UEs into account. Thus, data may be scheduled for UEs when channel propagations allow for this to be communicated with low resource usage. However, in order to enable this scheduling to be sufficiently fast to follow the dynamic variations, HSDPA requires that the scheduling is performed at the base station rather than by the RNC. Locating a scheduling function in the base station eliminates the requirement for communication over the base station to RNC interface (the Iub interface) thereby reducing the significant delays associated therewith.

In order for the scheduling to be efficient, the base station scheduler needs current information of the channel conditions. Accordingly, in a TDD HSDPA system, the mobile station provides information by transmitting this information to the base station using a channel which is controlled by the downlink scheduler. Uplink resources (denoted HS-SICH) are implicitly assigned when the UE receives an allocation for downlink HSDPA data, such that a positive or negative acknowledgement of that downlink data may be returned to the base station based downlink scheduler. In addition to transmitting the acknowledgement information on the implicitly-assigned uplink physical resources, the UE also includes current information of the channel conditions. Thus, information is transmitted to the scheduler on the HS-SICH which is set up and controlled by the scheduler controlling the HSDPA communication. Furthermore, dedicated resources are used for the uplink signaling and the HS-SICH may be permanently set up to provide the required information.

It has recently been proposed to introduce an uplink packet data service similar to HSDPA. In particular, such a service would utilise a base station based scheduler to schedule user data on an uplink packet channel. However, in order for such a system to operate efficiently, it is necessary that the scheduler is provided with information from the UE with a minimum of delay. It has been proposed to provide this information by including the information with the uplink user data. Specifically, it has been proposed to piggyback the data on the used data packets by including such data in the MAC-e header of the uplink user data PDUs (Packet Data Units).

However, a solution where the signaling data is transmitted in user data PDUs is suboptimal in many situations. In particular, it leads to an inflexible system and restricts the scheduling efficiency. Specifically, in order to achieve an efficient communication of the user data, it has been proposed to use a retransmission scheme for the PDUs. In particular, it has been proposed to use an ARQ scheme wherein previous transmissions of PDUs are combined with the retransmissions in the receiver. However, in order for such a scheme to operate efficiently, the PDU error rate is selected to be relatively high, resulting in a low resource usage of each PDU but a significant number of retransmissions. Thus, the signaling data for the base station scheduler will inherently have a high error rate and will typically require retransmissions before being correctly received. However, this introduces a very substantial delay which significantly reduces the achievable performance of the scheduler. In particular for a TDD system, an increased delay may significantly affect the performance which can be achieved.

In the following, some embodiments are described wherein an efficient sharing of a physical resource between scheduling assistance data and other data is achieved while ensuring that the delay of the scheduling assistance data is reduced thus resulting in improved scheduling performance, improved end user perceived quality of service and improved performance of the cellular communication system as a whole.

FIG. 2 illustrates the UE 101, the RNC 107 and the base station 105 of the example of FIG. 1 in more detail. In the example, the RNC 107 comprises an RNC scheduler 201 which is responsible for scheduling conventional 3GPP physical channels such as for example a Dedicated Physical CHannel (DPCH) as will be known to the person skilled in the art. Thus, the RNC scheduler 201 schedules data for communication over the air interface as defined in Release 99 of the 3GPP technical specifications.

In the example of FIG. 2, the base station 105 comprises an RNC interface 203 which is responsible for communicating with the RNC 107 over the Iub interface. The RNC interface 203 is coupled to a base station controller 205 which controls the operation of the base station 105. The base station controller 205 is coupled to a transceiver 207 which is operable to communicate with the UE 101 over the air interface. The base station controller 205 performs all the functionality required for transmitting data received from the RNC 107 to the UE 101 as well as for receiving and forwarding data received from the UE 101 to the RNC 107.

The base station 105 furthermore comprises a base station scheduler 209 which is coupled to the base station controller 205. The base station scheduler 209 is responsible for scheduling data for an uplink packet data service which may be an uplink shared packet data service. Specifically, the base station scheduler 209 schedules user data on a shared transport channel of a shared physical resource and generates resource allocation information for the shared physical resource. The allocation information is fed to the base station scheduler 209 and transmitted to the UEs 101, 103 over the air interface.

As the base station scheduler 209 is located in the base station 105, it can schedule data without the additional delay required for communication of allocation information over the Iub interface (as required for the RNC scheduler 201).

The base station scheduler 209 schedules data for the uplink transport channel based on different information. In particular, the base station scheduler 209 may schedule data in response to the individual air interface channel propagation characteristics and the current transmit buffer requirements of the UEs. Accordingly, this information is preferably obtained from scheduling assistance data which is transmitted to the base station 105 from the UEs 101, 103. In order to have an efficient scheduling, the scheduling assistance data is preferably received with low delay and frequent intervals. Accordingly, it is desirable that the scheduling assistance data is provided to the base station scheduler 209 without it first being transmitted to and received from the RNC 107 over the Iub interface.

In the example of FIG. 2, the UE 101 comprises a transceiver 211 which is operable to communicate with the base station 105 over the air interface in accordance with the 3GPP Technical Specifications. It will be appreciated the UE 101 furthermore comprises the required or desired functionality for a UE of a 3GPP cellular communication system.

The UE 101 comprises a channel controller 213 which is operable to allocate data to individual physical resources in accordance with the 3GPP Technical Specifications. In the specific example of FIG. 2, the UE 101 is involved in a user data communication and comprises a user data source 215 which generates user data to be transmitted to the RNC 107. The user data source 215 is coupled to a first transport channel controller 217 which allocates the user data to an appropriate transport channel (henceforth referred to as the user data transport channel) such as the uplink Dedicated Channel (DCH) or the Uplink Shared Channel (USCH).

The first transport channel controller 217 is further coupled to a retransmission controller 219. The retransmission controller 219 is coupled to the transceiver and is arranged to operate a retransmission scheme for the transport channel used for the user data (i.e. the DCH). The retransmission scheme is particularly an ARQ retransmission scheme controlled by the RNC 107 in accordance with the 3GPP Technical Specifications.

If a data packet comprising user data is acknowledged by the RNC 107, the transceiver 211 feeds the acknowledgement to the retransmission controller 219. The retransmission controller 219 thus monitors the received acknowledgements and detects if a data packet has not been acknowledged. If this occurs, the retransmission controller 219 informs the first transport channel controller 217 which proceeds to include this data in the DCH transport channel for the next (or a subsequent) PDU to be transmitted to the base station 105. Thus, the first transport channel controller 217 ensures that all user data is received by the base station even if packet errors occur.

In the example of FIG. 2, the UE 101 is furthermore involved in a packet data communication which is scheduled by the base station scheduler 209. For example, the UE 101 may be involved in an Internet access application supported by an uplink packet data service. In the example, the UE 101 comprises a packet data transmit buffer 221 which stores the packet data until it is scheduled for transmission over the uplink channel which specifically may be an uplink shared channel. However, in contrast to the communication of the user data from the user data source, the scheduling for this packet data communication is performed by the base station scheduler 209 rather than by the RNC scheduler 201.

The packet data transmit buffer 221 is coupled to the channel controller 213 which is arranged to transmit the packet data to the base station 105 using an appropriate physical resource and transport channel controlled by the base station scheduler 209. Specifically, the channel controller 213 may transmit the packet data on an Enhanced Dedicated CHannel (E-DCH).

The packet data transmit buffer 221 is coupled to a scheduling assistance data generator 223 which generates scheduling assistance data for transmission to the base station 105. In particular, the scheduling assistance data relates to information that is available at the UE 101 and which may be used by the base station scheduler 209 when scheduling data.

In the UE 101 of FIG. 2, the scheduling assistance data generator 223 is coupled to the packet data transmit buffer 221 and obtains dynamic information of the current buffer loading from this. Thus, the scheduling assistance data generator 223 determines how much data is currently stored in the packet data transmit buffer 221 pending transmission over the uplink channel.

The scheduling assistance data generator 223 includes an indication of this pending transmit data amount in the scheduling assistance data. Furthermore, the scheduling assistance data generator 223 may be provided with information which is indicative of the current propagation conditions and may include this information in the scheduling assistance data. The propagation conditions for the physical resource may for example be determined from signal level measurements on received signals. In the example of a TDD system, this downlink propagation data may be considered applicable for the uplink propagation data as well since both uplink and downlink use the same frequency.

The scheduling assistance data generator 223 is coupled to a second transport channel controller 225 which allocates the scheduling assistance data to a second transport channel, henceforth referred to as the signaling transport channel.

The first transport channel controller 217 and the second transport channel controller 225 are coupled to a transport channel multiplexer 227 which is arranged to multiplex the user data transport channel and the signaling transport channel. The transport channel multiplexer 227 is further coupled to the channel controller 213 which is operable to transmit the first and second transport channels as multiplexed transport channels on a physical resource.

Thus, in the example, the scheduling assistance data is transmitted on the same physical resource as the user data by the physical resource being shared by two different transport channels. For example, a given PDU transmitted over the air interface may comprise data from both the user data transport channel and the signaling transport channel. Furthermore, an efficient and optimized shared communication is achieved where one transport channel employs a retransmission scheme whereas the other transport channel does not. In particular, the user data is transmitted using a retransmission scheme which may provide a highly efficient and low resource communication but may also have a significant delay. The scheduling assistance data may be transmitted on a signaling transport channel which does not employ a retransmissions scheme. Thus the base station scheduler 209 does not need to await retransmissions before scheduling data.

It will be appreciated that in some embodiments, the packet data transmit buffer may be transmitted on the first transport channel. Thus in some embodiments, the scheduling assistance data may be transmitted on a transport channel which is multiplexed onto the same resource with a transport channel carrying the data to which the scheduling assistance data relates, whereas in other embodiments it may be multiplexed with a transport channel carrying other data and possibly being unrelated to the uplink data communication of the packet data from the packet data transmit buffer. The first transport channel may e.g. carry user data, control data or other signaling data.

In the example of FIG. 2, the user data transport channel is a DCH channel for which the retransmission is controlled by the RNC 107. In such embodiments, the RNC 107 may transmit an acknowledge message to the UE 101 only when it receives a correctly received PDU from the base station 105. Thus, if the base station 105 receives a PDU without being able to successfully decode it, the received symbol samples may be stored. As no acknowledge is sent to the UE 101 this will retransmit the PDU and when the new transmission is received by the base station 105, the data is combined with the stored symbol samples. If this allows the PDU to be recovered, this is sent to the RNC 107 which in return transmits the acknowledge message to the UE 101. Otherwise, the base station 105 stores the data and awaits the next retransmission from the UE 101.

In other embodiments, the retransmission may be controlled elsewhere. For example, in some embodiments, when the base station 105 successfully receives the PDUs from the UE 101, the base station controller 205 generates an acknowledge message which is transmitted to the UE 101 by the transceiver 207. Thus, in this example, the retransmission is controlled by the base station 105. The retransmission scheme may in such embodiments particularly be a Hybrid ARQ scheme.

In the example of FIG. 2, the channel controller 213 transmits the scheduling assistance data over a physical resource which is not managed by the base station based scheduler. In particular, the channel controller 213 selects a physical channel which is controlled by the RNC scheduler 201.

As an example, the channel controller 213 may transmit the scheduling assistance data on a dedicated physical resource used for a circuit switched voice call. Specifically, the channel controller may piggyback the scheduling assistance data together with a DPDCH which has been set up and is controlled by the RNC scheduler 201, onto DPCH physical resources assigned which are again set up and controlled by the RNC scheduler 201. As another example, the channel controller may transmit the scheduling assistance data on a Random Access CHannel (the PRACH channel).

When the communication is received at the base station 105, the base station controller 205 is in the example of FIG. 2 arranged to extract the scheduling assistance data and to feed it to the base station scheduler 209. For example, the base station controller 205 may monitor the DPDCH and/or the PRACH and when it detects that scheduling assistance data is being received, it may decode this data and send it to the base station scheduler 209.

It will be appreciated that in some embodiments, the RNC scheduler 201 may specifically allocate segments of the physical resource for the communication of scheduling assistance data and information identifying these segments may be communicated both to the base station 105 and the UE 101.

The scheduling assistance data is thus in this example received on a physical resource which is shared by other services supported by scheduling in the RNC. In some embodiments, the scheduling assistance data may be received on a physical resource which is supported by a different scheduler in the base station 105, such as in the case of HS-SICH for HSDPA. Specifically, these services may be conventional release 99, release 4 or release5 services. Thus, an efficient and flexible communication of scheduling assistance data is achieved while maintaining backwards compatibility and avoiding the requirement of the base station scheduler 209 needing to allocate resource for scheduling assistance data. Rather, in many situations, unused resource of the RNC scheduled physical resources may be used for communication of scheduling assistance data.

Furthermore, the system of FIG. 2 allows a very fast communication of scheduling assistance data as the signaling avoids the delay inherent in communication over the Iub interface between the base station 105 and the RNC 107.

In the example, the base station scheduler 209 may be provided with scheduling assistance data indicative of the air interface channel conditions and the transmit data requirements of UEs 101, 103 at frequent intervals (due to the efficient resource utilization) and with very low delays. This allows a much faster scheduling taking into account fast varying characteristics and thus results in a much improved scheduling. This leads to an improved resource usage and increased capacity of the cellular communication system as a whole.

In the example of FIG. 2, the scheduling assistance data is communicated on a signaling transport channel. A transport channel may be a channel that carries PDUs to and from the physical layer and the MAC layer. A physical channel carries bits over the air interface. A physical channel is specifically a Layer 1 (Physical layer) channel. A logical channel carries PDUs between the MAC layer and the RLC (Radio Link Control) layer.

Specifically, for 3GPP systems, a transport channel is an information-bearing interface between a 3GPP Multiple Access Control (MAC) entity, and a 3GPP physical layer entity. A physical channel is a unit of transmission resource, defined in 3GPP as a specific spreading code and period of time occupancy on the air interface; a unit of transmission resource. A logical channel is an information-bearing interface at the transmission input to the MAC.

In the system of FIG. 2, the physical resource supports two or more transport channels which are multiplexed onto the same physical resource. Specifically, a new transport channel may be defined for communication of the scheduling assistance data and this transport channel may be multiplexed together with one or more DCH(s) onto one or more physical DPCH channels on which the DCH(s) are carried in a 3GPP system.

For a 3GPP system, two or more separate information streams may be multiplexed onto a common set of physical resources in several ways:

Physical Layer Field Multiplexing

For physical layer field multiplexing, the multiple information streams are separately encoded (if required) and occupy mutually exclusive (and usually contiguous) portions of the transmission payload. De-multiplexing is achieved by extracting the relevant portions of the transmission payload for each stream and treating them independently thereafter.

Transport Channel Multiplexing

For transport channel multiplexing, the multiple information streams are separately encoded and a coordinated rate matching scheme is applied to each stream such that the total number of bits after rate matching exactly fits the transmission payload. Generally, this is similar to physical layer multiplexing except that the bits corresponding to each information stream are usually non-contiguous in the final transmission payload. Additionally, the rate matching scheme is designed in such a way that the amount of FEC applied to each stream may be varied in a flexible manner, allowing for various and differing quality requirements to be met independently for each stream. De-multiplexing is enabled via the receiver having knowledge of the rate matching scheme algorithm applied in the transmitter.

Logical Channel Multiplexing

For logical channel multiplexing, the multiple information streams are multiplexed by the MAC layer prior to forward error correction encoding by the physical layer, with a header being applied to each stream to enable de-multiplexing in the receiver. FEC encoding is applied to the composite (multiplexed) stream, and so each stream will experience the same transmission reliability.

It will be appreciated that although the physical resource, such as the DPCH channel, is controlled by the RNC scheduler, the transport channel used for the scheduling assistance data is preferably terminated at the base station 105 while the dedicated transport channel, the DCH, is terminated at the RNC 107. Thus, although the transport channel used for the scheduling assistance data and the transport channel used for other data are multiplexed onto the same physical resource, they terminate in different entities. This may allow a particularly efficient and flexible signaling and may in particular minimize the delay for the scheduling assistance data. Specifically, it may avoid the delay associated with receiving the scheduling assistance data on a RNC terminated transport channel and retransmitting this to the base station 105.

The UE 101 of FIG. 2 employs transport channel multiplexing. Multiplexing of the transport channels provides a number of advantages and options particularly suitable for the described embodiments.

For example, in contrast to physical layer multiplexing, it enables the uplink signaling to be multiplexed with legacy channels (e.g. Release 99 defined channels) without having a large impact on the 3GPP Technical Specifications.

Furthermore, existing approaches for transport channel multiplexing within 3GPP may be re-used with minimal impact on the Technical Specifications and thus improved backwards compatibility may be achieved.

Furthermore, usage of transport channel multiplexing may be used to individually optimize performance for the individual transport channels. In some embodiments, different transmission schemes are used for the different transport channels. In particular, different transmission schemes resulting in different transmission reliabilities may be used.

As a specific example, the forward error correction coding may be selected individually for each transport channel and for example a higher reliability forward error correction coding may be selected for the signaling transport channel than for the user data transport channel.

As a specific example, the first transport channel controller 217 may apply a first forward error correction coding scheme, such as a ½ rate Viterbi encoding scheme whereas the second transport channel controller 225 may apply a different encoding scheme or may use a different encoding rate. For example, the second transport channel controller 225 may apply a ⅓ rate Viterbi encoding scheme.

In some such embodiments, the transport channel multiplexer 227 may simply multiplex the transport channels by combining the data of the first transport channel controller 217 and the second transport channel controller 225 in the PDUs to be transmitted on the physical resource.

In the specific example, a higher transmission reliability would thus be achieved for the scheduling assistance data than for the user data. The effective bit error and thus packet data error rate may be selected to be substantially lower, say by a factor of ten, for signaling transport channel than for the user data transport channel.

This may be highly advantageous as a high link efficiency may be obtained for the user data due to the low resource usage per data packet combined with retransmissions. At the same time, a highly reliable transmission of scheduling assistance data may be achieved. This communication may ensure that the scheduling assistance data may be received from a first transmission even if the user data cannot be determined from the received signal. Thus, an increased reliability and reduced delay for the scheduling assistance data is achieved.

As another example, the first transport channel controller 217 and the second transport channel controller 225 may provide different transmission reliabilities by using different modulation schemes. For example, the first transport channel controller 217 may generate a user data transport channel using 8-PSK (Phase Shift Keying) symbols whereas the second transport channel controller 225 may use QPSK (Quaternary Phase Shift Keying) data symbols.

In some embodiments, the transport channel multiplexer 227 is further operable to perform rate matching for the user data and signaling transport channels. This may allow the channel data allocated to a PDU by the first transport channel controller 217 and the second transport channel controller 225 to be adjusted to match the capacity of the PDU. The transport channel multiplexer 227 may specifically in some embodiments apply different rate matching characteristics to the user data transport channel and the signaling transport channel.

For example, rate matching may include puncturing of the encoded data output of the first transport channel controller 217 and/or the second transport channel controller 225. Puncturing of a code comprises removing some redundant symbols from the encoded data and may be used to reduce the resulting encoded data rate.

Alternatively or additionally, rate matching may include repeating some of the encoded data from the first transport channel controller 217 and/or the second transport channel controller 225. Repetition of encoded symbols comprises repeating some of the symbols from the encoded data and may be used to increase the resulting encoded data rate.

Furthermore, increased puncturing may increase the resulting error rates whereas repetition may reduce the error rates. Thus, by adjusting the puncturing and repetition characteristics, the transport channel multiplexer 227 may adjust the reliability of the transmitted data and by using different puncturing and repetition for the two transport channels different transmission reliabilities are achieved.

The transport channel multiplexer 227 may specifically use puncturing and repetition to both obtain a desired data rate or data volume while obtaining a desired relative reliability difference between the user data transport channel and the signaling transport channel.

Thus, in the example, the user data transport channel employs a retransmission scheme where faulty data packets are retransmitted from the UE 101 whereas the signaling transport channel does not employ a retransmission scheme but rather transmits the data with a more reliable error coding. In the example, a single physical resource may comprise a first transport channel used for transmission of non-delay-sensitive data. The transmissions may have a high data packet error rate of, say, 10-30% resulting in a large number of retransmissions and thus increased delay but also in a very efficient resource utilization. At the same time, the physical resource may support a signaling transport channel used for the transmission of the scheduling assistance data and this transport channel may have a very low data rate thus ensuring that the packet data is received reliably and with a low delay resulting in improved scheduling by the base station scheduler 209.

It will be appreciated that e.g. physical resources controlled by the RNC 107 may be used to support the communication of the scheduling assistance data.

For example, as described, a DPCH or PRACH physical channel may be used. In some embodiments, the UE 101 and base station 105 may additionally comprise functionality for communicating the scheduling assistance data on a physical resource which is managed by the base station scheduler 209. Thus, in this example, the UE 101 may comprise functionality for communicating on a number of different physical resources. In the example of FIG. 2, a suitable physical resource on which to communicate the scheduling assistance data may be selected depending on the current conditions and operating environment and a suitable physical channel may be selected to provide the best performance for the current conditions.

Thus, in this example the signaling used to assist the enhanced uplink scheduling process by the base station scheduler 209 is intelligently routed and transmitted on different uplink physical resources according to the current preferences and conditions. In particular, a physical resource may be selected based on the presence or absence of those uplink physical resources. The scheduling assistance data may furthermore be communicated in a transport channel which is terminated in the base station 105.

In an alternative approach, the signaling used to assist the enhanced uplink scheduling process by the base station scheduler 209 may be routed and transmitted on different transport channels, and hence, physical resources, under the control of the network, via network-to-UE signaling means.

The intelligent-routing approach will be illustrated with reference to an example where three specific configurations are considered:

Scenario 1:

The user equipment 101 intends to inform the base station scheduler 209 about its current packet data transmit buffer status or radio conditions, yet no enhanced uplink resources have been granted for transmission and no other uplink radio resources are in existence or are available. This situation is common when the UE 101 has previously finished transmission of a packet call, has been idle for a period of time, and new data arrives in the UE's 101 packet data transmit buffer 221. The user must then inform the base station scheduler 209 of its need for transmission resources to transmit the new data.

Scenario 2:

The user equipment 101 intends to update the base station scheduler 209 with new air interface condition information or buffer information and packet data uplink resources scheduled by the base station scheduler 209 are already available. In this case, the UE 101 may piggyback the uplink signaling using a part of the resources granted for transmission of the uplink packet data transmission itself.

Scenario 3:

The user equipment 101 intends to update the base station scheduler 209 with new channel or buffer information, no packet data uplink resources managed by the base station scheduler 209 are available, yet other RNC managed uplink resources are in existence and are available. In this case, the UE 101 may piggyback the signaling using a part of the existing uplink resources.

Thus, in some embodiments the channel controller 213 of the UE 101 and the base station controller 205 of the base station 105 comprise functionality for selecting between different physical resources. Furthermore, this selection may be performed in response to whether the different physical resources are available.

As a specific example, the channel controller 213 may first evaluate if an uplink packet data channel controlled by the base station scheduler 209 is available. If so, this channel is selected for transmission of the scheduling assistance data. Otherwise, the channel controller 213 may evaluate if an uplink physical channel controlled by the RNC scheduler 201 is set up (such as a DPCH). If so, the scheduling assistance data is transmitted on this channel. However, if no such channel is available, the channel controller 213 may continue to transmit the scheduling assistance data using a random access channel (the PRACH).

In different embodiments, the selection of physical resources may be made in response to different parameters or characteristics. For example, the channel controller 213 and base station controller 205 may take into account parameters such as:

The presence or absence of uplink physical resource types.

The time since an uplink physical resource type was last present. For example, a given physical resource may be selected only if it has been available within a given time interval.

The traffic loading of channels mapped to the uplink resource types. For example, a physical resource may be selected if the traffic loading is so low that there is spare available resource.

A consideration of the transmission latency of the uplink signaling. For example, each physical resource may have an associated latency due to signaling delays, encoding etc. and the physical resource having the lowest latency may be selected in preference to other physical resources.

Alternatively or additionally, the selection of the physical resource may be performed in response to a configuration by the fixed network and in particular the RNC. For example, some signaling routes may be explicitly allowed or disallowed by the fixed network.

The selection of physical resources may for example be made by selecting a transport channel and then selecting a physical resource on which to transmit this transport channel. As another example, the selection of physical resources may be made by having different transport channels linked to different physical channels and then selecting the appropriate transport channel.

FIG. 3 illustrates the principles between these exemplary switching embodiments. In particular, FIG. 3 a illustrates an example of the switching of a single transport channel between uplink physical resource types and FIG. 3.b illustrates an example of the switching of the signaling information stream into two or more transport channels each having a fixed association with a physical resource type.

In the example of FIG. 3 a, the scheduling assistance data is included in a new transport channel (TrCH #1). The transport channel is then switched either to a first or second transport channel multiplexer depending on the desired physical resource type. The selected transport channel multiplexer multiplexes the transport channels with other transport channels to be communicated on the physical resource.

In the example of FIG. 3 b, the scheduling assistance data is either included in a first transport channel (TrCH #1 ) or a second transport channel (TrCH #2). Each of the transport channels is supported by a different physical resource and the selected transport channel is multiplexed with other transport channels before being transmitted on the physical resource. The selection of the specific transport channel for the scheduling assistance data may be made in response to characteristics of the physical resources associated with the individual transport channels.

In some embodiments the transport channels of the physical resource may be terminated at different points in the fixed network. Specifically, a transport channel may be used for user data communication and may be terminated at the RNC 107 while a second transport channel is used for communication of the scheduling assistance data and is terminated in the base station 105. Thus, the same physical resource may support transport channels which are individually terminated at the optimum location. This may reduce delays associated with the scheduling assistance data and may improve the scheduling performance of the base station scheduler 209.

FIG. 4 illustrates an example of a signaling system in accordance with some embodiments of the invention. The illustrated functionality may specifically be implemented in the channel controller 213 of FIG. 2. The operation will be described with reference to the three specific exemplary 3GPP UTRAN TDD scenarios previously described.

Scenario 1

In scenario 1, due to the fact that the existing RACH is terminated in the RNC 107, the base station 105 cannot make use of this transport channel to carry the necessary uplink signaling. The RACH is not “visible” to the base station 105 and simply passes through it on its way to the RNC. It would be possible to forward the received information back from the RNC to the Node-B via new Iub signaling although this technique suffers greatly from the latency involved in these multiple transmission legs.

Non-random-access methods may also be considered (such as circular polling) but such techniques again suffer from potential latency increases (there is a potential significant delay between data arriving in the user's transmission buffer(s) and uplink resources being granted to serve that data).

In accordance with the example of FIG. 4, a new base station terminated random access channel which is able to convey the scheduling assistance data directly to the base station scheduler 209 is defined.

The new random access channel is termed “E-SACH_(R)” (Enhanced Uplink Scheduler Assistance Channel) in the example of FIG. 4. The “R” subscript relates to the fact that the channel is random access in nature (ie: non-scheduled and in particular not scheduled or managed by the base station scheduler 209). The channel is able to carry an indication to the base station scheduler 209 that new data has arrived in the user's transmission buffer and is in effect a request for uplink radio resources. It may also carry an indication of the current channel conditions and, because the transmission is random access, it may also carry an indication of the user identity such that the base station scheduler 209 knows which user to allocate the resources to.

Scenario 2

With the uplink data payload being carried on one transport channel scheduled by the base station scheduler 209 (denoted the Enhanced—Dedicated CHannel—E-DCH), the uplink signaling may be carried on a separate transport channel (denoted E-SACH_(E) in FIG. 4). Like E-SACH_(R), E-SACH_(E) is terminated at the base station 105. The “E” subscript is used to denote that the scheduling assistance information is piggy-backed on the enhanced uplink transmission scheduled by the base station scheduler 209. However, because it is conveyed on a scheduled transmission, the need to carry the user identity in the signaling is obviated. Thus, the PDU size of an E-SACH_(E) PDU is likely to be different to that of an E-SACH_(R) PDU. The two (or more) transport channels are multiplexed onto the same set of physical resources (termed a CCTrCH). Furthermore, it is possible to adjust the degree of FEC coding applied to E-SACH_(E) and E-DCH, to optimize the transmission reliability of each transport channel as desired. For example, it may be desirable for the E-SACH_(E) to be given a higher degree of FEC protection than the E-DCH, such that the scheduler information gets to the scheduler with high reliability (usually in a single transmission) whilst the E-DCH is able to utilize the ARQ (retransmission) efficiencies by operating each transmission instance at optimum link reliability (often involving multiple transmissions per unit of data before it is received without error).

Scenario 3

This scenario is similar to that of scenario 2, with the key difference being that the uplink signaling is piggybacked on uplink resources which are not directly associated with the enhanced uplink transmission and which are not scheduled by the base station scheduler 209. These uplink resources are here termed “auxiliary”. For example, enhanced packet data uplink may be used in conjunction with the HSDPA downlink packet data service. In such a case an associated uplink DCH exists (typically used to carry higher layer user data such as TCP (Transmit Power Control) acknowledgements, and layer 3 control traffic to control events (such as handovers). The scheduling assistance data may in such a case be transmitted on uplink DPCH physical resources or on another uplink HSDPA channel such as the HS-SICH (High Speed-Shared Information Channel).

When no other uplink transmission resources are available, but there is a need to send updated information to the scheduler, it may be preferable (for latency reasons or to reap efficiency savings) for the user to piggyback the uplink signaling of scheduling assistance data onto the auxiliary uplink resources, rather than using the E-SACH_(R) random access procedures.

Again, in order to facilitate control over the degree of forward error correcting coding applied to the auxiliary traffic and the uplink signaling, and to enable separate detection of each, a separate transport channel is used for the uplink signaling, termed the E-SACH_(D). As in scenario 2, the E-SACH_(D) is terminated at base station 105 and is multiplexed together with other data onto a common set of auxiliary uplink radio resources (the auxiliary uplink CCTrCH).

It will be appreciated that the above description for clarity has described embodiments of the invention with reference to different functional units and processors. However, it will be apparent that any suitable distribution of functionality between different functional units or processors may be used without detracting from the invention. For example, functionality illustrated to be performed by separate processors or controllers may be performed by the same processor or controllers. Hence, references to specific functional units are only to be seen as references to suitable means for providing the described functionality rather than indicative of a strict logical or physical structure or organization.

The invention can be implemented in any suitable form including hardware, software, firmware or any combination of these. The invention may optionally be implemented at least partly as computer software running on one or more data processors and/or digital signal processors. The elements and components of an embodiment of the invention may be physically, functionally and logically implemented in any suitable way. Indeed the functionality may be implemented in a single unit, in a plurality of units or as part of other functional units. As such, the invention may be implemented in a single unit or may be physically and functionally distributed between different units and processors.

Although the present invention has been described in connection with some embodiments, it is not intended to be limited to the specific form set forth herein. Rather, the scope of the present invention is limited only by the accompanying claims. Additionally, although a feature may appear to be described in connection with particular embodiments, one skilled in the art would recognize that various features of the described embodiments may be combined in accordance with the invention. In the claims, the term comprising does not exclude the presence of other elements or steps.

Furthermore, although individually listed, a plurality of means, elements or method steps may be implemented by e.g. a single unit or processor. Additionally, although individual features may be included in different claims, these may possibly be advantageously combined, and the inclusion in different claims does not imply that a combination of features is not feasible and/or advantageous. Also the inclusion of a feature in one category of claims does not imply a limitation to this category but rather indicates that the feature is equally applicable to other claim categories as appropriate. Furthermore, the order of features in the claims do not imply any specific order in which the features must be worked and in particular the order of individual steps in a method claim does not imply that the steps must be performed in this order. Rather, the steps may be performed in any suitable order. In addition, singular references do not exclude a plurality. Thus references to “a”, “an”, “first”, “second” etc do not preclude a plurality. 

1. An apparatus for transmitting signaling information in a cellular communication system; the apparatus comprising: means for generating scheduling assistance data for a base station based scheduler, the scheduling assistance data relating to packet data communication of a User Equipment; means for allocating the scheduling assistance data to a first channel; means for allocating other data to a second channel; means for transmitting the first and second channel as multiplexed channels on a first physical resource; wherein the second channel employs a retransmission scheme and the first channel does not employ a retransmission scheme; means for transmitting the scheduling assistance data using a second physical resource; selection means for selecting between the first physical resource and the second physical resource, wherein the selection means is configured to select between the first physical resource and the second physical resource in response to a resource availability characteristic of the first physical resource and the second physical resource.
 2. The apparatus claimed in claim 1 wherein the means for transmitting is arranged to transmit the first and second channels with different transmission reliabilities.
 3. The apparatus claimed in claim 2 wherein the means for transmitting is arranged to transmit the first channel with a lower bit error rate than for the second channel.
 4. The apparatus claimed in claim 1 wherein the means for transmitting is arranged to transmit the first channel in accordance with a first transmission scheme and to transmit the second channel in accordance with a different second transmission scheme.
 5. The apparatus claimed in claim 4 wherein the first transmission scheme and the second transmission scheme comprise different error correcting encoding.
 6. The apparatus claimed in claim 1 wherein the means for transmitting is arranged to perform rate matching of the first channel and the second channel.
 7. The apparatus claimed in claim 6 wherein the means for transmitting is arranged to apply different rate matching characteristics to the first channel and the second channel.
 8. The apparatus claimed in claim 1 wherein the first channel is terminated in a base station of the base station based scheduler.
 9. The apparatus claimed in claim 1 wherein the first channel has a different termination point than the second channel.
 10. The apparatus claimed in claim 1 wherein the retransmission scheme is a Radio Network Controller controlled retransmission scheme.
 11. The apparatus claimed in claim I wherein the retransmission scheme is a Base Station controlled retransmission scheme.
 12. The apparatus claimed in claim 1 wherein the retransmission scheme is a Hybrid Automatic Repeat reQuest, ARQ, retransmission scheme.
 13. The apparatus claimed in claim 1 wherein the selection means is arranged to select between the first physical resource and the second physical resource in response to a traffic loading of the first physical resource and the second physical resource.
 14. The apparatus claimed in claim 1 wherein the first physical resource is not managed by the base station scheduler.
 15. The apparatus claimed in any of the claims 1, 13, and 14 wherein the second physical resource is a physical resource managed by the base station based scheduler.
 16. The apparatus claimed in claim 1 wherein the first physical resource is associated with the first channel and the second physical resource is associated with a third channel and the selection means is arranged to allocate the scheduling assistance data by associating the scheduling assistance data with the first or third channel.
 17. The apparatus claimed in claim 1 wherein the first physical resource is a random access channel.
 18. The apparatus claimed in claim 1 wherein the packet data communication is an uplink packet data communication.
 19. The apparatus claimed in claim 1 wherein the cellular communication system is a 3 ^(rd) Generation Partnership Project, 3GPP, system.
 20. The apparatus claimed in claim 1 wherein the cellular communication system is a Time Division Duplex system.
 21. An apparatus for receiving signaling information in a cellular communication system; the apparatus comprising: selection means for selecting between a first physical resource and a second physical resource, wherein the selection means is configured to select between the first physical resource and the second physical resource in response to a resource availability characteristic of the first physical resource and the second physical resource; means for receiving the first physical resource comprising a first channel and a second channel as multiplexed channels; means for receiving the second physical resource comprising the first channel; means for extracting scheduling assistance data for a base station based scheduler from the first channel, the scheduling assistance data relating to packet data communication of a User Equipment; means for extracting other data from the second channel; and wherein the second channel employs a retransmission scheme and the first channel does not employ a retransmission scheme.
 22. A method of transmitting signaling information in a cellular communication system; the method comprising: generating scheduling assistance data for a base station based scheduler, the scheduling assistance data relating to packet data communication of a User Equipment; selecting between a first physical resource and a second physical resource, wherein the first or second physical resource is selected in response to a resource availability characteristic of the first physical resource and the second physical resource; allocating the scheduling assistance data to a first channel; allocating other data to a second channel; transmitting the first channel and second channel as multiplexed channels on the first physical resource if the first physical resource is selected, wherein the second channel employs a retransmission scheme and the first channel does not employ a retransmission scheme; transmitting the scheduling assistance data using the second physical resource if the second physical resource is selected.
 23. The method claimed in claim 22 wherein the first channel and the second channel are transmitted with different transmission reliabilities.
 24. The method claimed in claim 22 wherein the first channel is transmitted in accordance with a first transmission scheme and the second channel is transmitted in accordance with a different second transmission scheme.
 25. The method claimed in claim 22 wherein the first channel is terminated in a base station of the base station based scheduler.
 26. A method of receiving signaling information in a cellular communication system; the method comprising: selecting between a first physical resource and a second physical resource, wherein the selection between the first physical resource and the second physical resource is in response to a resource availability characteristic of the first physical resource and the second physical resource; receiving the first physical resource comprising a first channel and a second channel as multiplexed channels, if the first physical resource is selected; receiving the second physical resource comprising the first channel if the second physical resource is selected; extracting scheduling assistance data for a base station based scheduler from the first channel, the scheduling assistance data relating to packet data communication of a User Equipment; extracting other data from the second channel, if the first physical resource is selected; and wherein the second channel employs a retransmission scheme and the first channel does not employ a retransmission scheme. 